Controlling energy transfer from intense ultrashort light pulse to crystals: A comparison study in attosecond and femtosecond regimes

Xiaoqin Zhang; Feng Wang; Zehui Liu; Xiurong Feng; Suna Pang

doi:10.1016/j.physleta.2020.126710

Controlling energy transfer from intense ultrashort light pulse to crystals: A comparison study in attosecond and femtosecond regimes

Xiaoqin Zhang, Feng Wang^*, Zehui Liu, Xiurong Feng, Suna Pang

^*Corresponding author for this work

School of Physics

Research output: Contribution to journal › Article › peer-review

5 Citations (Scopus)

Abstract

The energy exchange between photons and electrons has been investigated theoretically by ab initio approach based on time-dependent density functional theory. Using diamond as a concrete example, three types of resonance and cancellation in the transfer of energy are theoretically observed, that allows one to gain a useful independent insight into the interaction processes of attosecond light pulses with matter. Our results demonstrate the linearity in energy transfer from intense attosecond light pulses to solids, in contrast to the nonlinearity in energy transfer from intense femtosecond light pulses to solids as expected from the conventional point of view, opening new perspectives for attoscience.

Original language	English
Article number	126710
Journal	Physics Letters, Section A: General, Atomic and Solid State Physics
Volume	384
Issue number	27
DOIs	https://doi.org/10.1016/j.physleta.2020.126710
Publication status	Published - 28 Sept 2020

Keywords

Attosecond light pulse
Energy transfer
Ultrashort light-matter interaction

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title = "Controlling energy transfer from intense ultrashort light pulse to crystals: A comparison study in attosecond and femtosecond regimes",

abstract = "The energy exchange between photons and electrons has been investigated theoretically by ab initio approach based on time-dependent density functional theory. Using diamond as a concrete example, three types of resonance and cancellation in the transfer of energy are theoretically observed, that allows one to gain a useful independent insight into the interaction processes of attosecond light pulses with matter. Our results demonstrate the linearity in energy transfer from intense attosecond light pulses to solids, in contrast to the nonlinearity in energy transfer from intense femtosecond light pulses to solids as expected from the conventional point of view, opening new perspectives for attoscience.",

keywords = "Attosecond light pulse, Energy transfer, Ultrashort light-matter interaction",

author = "Xiaoqin Zhang and Feng Wang and Zehui Liu and Xiurong Feng and Suna Pang",

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T1 - Controlling energy transfer from intense ultrashort light pulse to crystals

T2 - A comparison study in attosecond and femtosecond regimes

AU - Zhang, Xiaoqin

AU - Wang, Feng

AU - Liu, Zehui

AU - Feng, Xiurong

AU - Pang, Suna

PY - 2020/9/28

Y1 - 2020/9/28

N2 - The energy exchange between photons and electrons has been investigated theoretically by ab initio approach based on time-dependent density functional theory. Using diamond as a concrete example, three types of resonance and cancellation in the transfer of energy are theoretically observed, that allows one to gain a useful independent insight into the interaction processes of attosecond light pulses with matter. Our results demonstrate the linearity in energy transfer from intense attosecond light pulses to solids, in contrast to the nonlinearity in energy transfer from intense femtosecond light pulses to solids as expected from the conventional point of view, opening new perspectives for attoscience.

AB - The energy exchange between photons and electrons has been investigated theoretically by ab initio approach based on time-dependent density functional theory. Using diamond as a concrete example, three types of resonance and cancellation in the transfer of energy are theoretically observed, that allows one to gain a useful independent insight into the interaction processes of attosecond light pulses with matter. Our results demonstrate the linearity in energy transfer from intense attosecond light pulses to solids, in contrast to the nonlinearity in energy transfer from intense femtosecond light pulses to solids as expected from the conventional point of view, opening new perspectives for attoscience.

KW - Attosecond light pulse

KW - Energy transfer

KW - Ultrashort light-matter interaction

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VL - 384

JO - Physics Letters, Section A: General, Atomic and Solid State Physics

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IS - 27

M1 - 126710

ER -

Controlling energy transfer from intense ultrashort light pulse to crystals: A comparison study in attosecond and femtosecond regimes

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